This invention relates generally to fuel delivery systems and more particularly to a carburetor.
Carburetors have been used to produce and control the delivery of a fuel and air mixture to an internal combustion engine. Some carburetors have a main body with an air intake passage extending therethrough and a throttle valve disposed in the air intake passage. The throttle valve is movable between an idle position and a wide open throttle position to control the flow of air through the carburetor.
In so-called butterfly-type carburetors, the throttle valve comprises a generally flat disk rotatable in the intake passage to vary the effective flow area of the air intake passage. Rotation of the throttle valve permits a vacuum pressure signal to act as a function of the position of the throttle valve on a plurality of fuel jets opening into the air intake passage. Thus, movement of the throttle valve controls the flow of fuel out of the various fuel jets whereupon the fuel is mixed with air flowing through the air intake passage. The fuel and air are mixed in the air intake passage and subsequently delivered to an engine to support its operation.
In so-called rotary throttle-type carburetors, a valve chamber extends perpendicular to the air intake passage and a cylindrical throttle valve shaft is received in the valve chamber. A hole through the throttle valve shaft is increasingly aligned with the air intake passage as the throttle valve is rotated from its idle position towards its wide open throttle position to control air flow in the carburetor. A needle carried by the throttle valve shaft is moved relative to a fuel nozzle as the throttle valve is rotated, to vary the effective flow area of the fuel nozzle. In this manner, the flow rate of fuel is adjusted according to the position of the throttle valve, and fuel discharged from the fuel nozzle mixes with air in the air intake passage for delivery of a fuel and air mixture to the engine.
A carburetor has an air intake passage, a fuel passage, a first valve in communication with the air intake passage and being movable between first and second positions, a second valve in communication with the fuel passage to vary the flow rate of fuel discharged from the fuel passage, and an actuator associated with the first and second valves to cause movement of one of them in response to movement of the other. So constructed and arranged, the first valve controls at least in part the air flow through the carburetor and the second valve controls at least in part the fuel flow from the carburetor.
Preferably, the actuator has a cam assembly associated with both the first and second valves which drives the second valve in response to movement of the first valve. In one form, the second valve has a needle that moves relative to a fuel nozzle opening to vary its effective flow area. In this form, the cam assembly retracts and advances the needle relative to the fuel nozzle in response to movement of the first valve. Preferably, the fuel nozzle opening is manufactured or cut into a substantially cylindrical tube, and is elongated in an axial direction with respect to the tube. A leading open end of the tube is then inserted and press fitted into a bore of the body. Once assembled, the open end is in communication with the fuel passage and the fuel nozzle opening. Insertion of the needle of the second valve into the tube controllably obstructs the fuel nozzle opening and thus controls the fuel flow through the open end of the tube.
In one form, the fuel nozzle opening communicates with the air intake passage so that a fuel and air mixture is discharged from the air intake passage for delivery to the engine. In a second form, the fuel nozzle opening communicates with a second air passage such that air is discharged from the air intake passage and a fuel and air mixture is discharged from the second air passage for delivery to the engine. Preferably, a method of manufacturing the tube of the fuel nozzle utilizes a circular rotating cutting tool which cuts the elongated slit into the tube while producing a sharp peripheral edge that atomizes fuel flowing through the opening. Of course, other forms or embodiments of the invention will be apparent to those skilled in the art.
Some of the objects, features and advantages of the invention include providing a carburetor that delivers all of the fuel for delivery to the engine through a single nozzle, has improved idle, rollout, acceleration and come down performance, has improved all position rollout, enables use of an air intake passage without a venturi throat, is readily adjustable, can be used with a fuel passage having a fixed or adjustable orifice, is of relatively simple design and economical manufacture and assembly and has a long useful life in service. Of course, other objects, features or advantages may be realized from the various possible embodiments of the invention, and some embodiments may realize fewer or more than the above listed objects, features and advantages.
These and other objects, features and advantages of the present invention will be apparent from the following detailed description of the preferred embodiments, appended claims and accompanying drawings in which:
Referring in more detail to the drawings,
In the embodiment shown, the carburetor 20 is a diaphragm-type carburetor that may utilize a conventional fuel circuit to receive fuel via a diaphragm-type fuel pump assembly and thereafter delivers fuel to a fuel metering assembly defined in part by a fuel metering diaphragm 40 received between the main block 26 and an end plate 42 of the carburetor body 22. The fuel metering assembly and the fuel pump assembly of the carburetor 20 may be constructed as shown and described in U.S. Pat. No. 5,262,092, the disclosure of which is incorporated herein by reference in its entirety. In general, on one side, the diaphragm 40 defines in part a fuel metering chamber 43 (FIG. 4) and on its other side an atmospheric reference chamber (not shown). An inlet valve controls the flow of fuel from the fuel pump into the metering chamber 43, and is actuated by movement of the fuel metering diaphragm 40.
As shown in
In the embodiment shown, the fuel nozzle opening 50 is open to the second air passage 46 so that in operation, a fuel and air mixture is delivered from the second air passage 46. Preferably, the nozzle 32 is disposed adjacent to an end of the second air passage 46 adjacent to the engine to increase the vacuum signal at the nozzle during operation of the engine and improve fuel flow through the fuel passage 30 and out of the fuel nozzle 32.
The first valve 28 is associated with the air intake passage 24 and has a valve shaft 60 extending through the main block 26 and the air intake passage 24. The shaft 60 is carried by the carburetor body 22 for rotation between first and second positions corresponding to an idle and wide open throttle engine operating conditions. A valve head 62 is carried by the valve shaft 60 and is preferably a flat disk rotatably received in the air intake passage 24. At idle, the valve head 62 is disposed substantially perpendicular to the air intake passage 24 and permits only a relatively low flow rate of air therethrough. At wide open throttle, the valve head 62 or disk is rotated so that it is generally parallel to the air flow through the intake passage 24 and permits a substantially free flow of air therethrough. A spring 64 on an end of the shaft 60 biases the first valve 28 towards its first position corresponding to idle engine operation. A valve lever 66 is disposed on the other end of the first valve shaft 60 and may be connected to a throttle cable so that the first valve 28 is rotated in response to desired engine performance between idle and wide open throttle. In
As best shown in
As best shown in
As best shown in
As best shown in
Accordingly, when the first valve 28 and its valve lever 66 are rotated in response to a desired change in engine operating conditions, the cam surface 76 is moved relative to the follower which is maintained in engagement with the cam surface 76 by the spring 90. Movement of the inclined cam surface 76 permits axial movement of the follower 88 and hence, the needle 86. This axial movement of the needle 86 changes its position relative to the fuel nozzle opening 50 to alter the effective flow area of the fuel nozzle 32.
When the first valve 28 is rotated from its first position towards its second position, the needle 86 is retracted relative to the fuel nozzle opening 50 to increase its effective flow area and permit increased fuel flow therethrough. At the same time, the bore 70 in the first valve shaft 60 becomes increasing aligned or registered with the second air passage 46 to permit increased airflow therethrough (designated by arrows 85 in
As generally shown in
More specific to the second or fuel valve 34, fuel flowing through a body portion 110 of the fuel passage 30 enters a bottom region 112 of a blind bore 114 formed into the body 26 and through a port 116 defined by the body 26, as best shown in
The tube 84 has an outer surface 124 which is slightly tapered, or generally transitions down in diameter, such that it is generally resembles a frustum shaped. The first or leading open end 118 of the tube 84 thus has a slightly smaller outer diameter 126 than an outer diameter 128 of an opposite or trailing open end 130 of the tube 84 through which the needle 86 extends, as best shown in FIGS. 3 and 11-14. During assembly, the elongated tube 84 is press fit into the elongated, generally blind, bore 114 of the body 26 which traverses or communicates substantially perpendicularly through the second air passage 46. The bore 114 extends longitudinally slightly beyond the air passage 46 placing the bottom portion or blind end 112 diametrically opposite to an opening or entry 132 of the bore and as viewed with respect to the air passage 46, as best shown in
To achieve a sealing press fit between the ends of the tube 84 and the body 26, the diameter of the bore 114 at the blind end 112 generally conforms to and is slightly less than the diameter 126 of the tube 84 at the leading end 118, and the diameter of the bore 114 at the opening 132 generally conforms to and is slightly less than the diameter 128 of the tube 84 at the trailing end 130. Consequently, when the tube 84 is completely inserted in the body 26, the taper of the bore 114 and the corresponding taper of the tube 84 preferably form a compression fit at both ends 118, 130 of the tube 84 with the body 26. Preferably, the tube 84 is made of brass and the carburetor body is made of cast aluminum. However, other fuel resistant materials known in the art may also be applied to achieve the same compression fit. For instance, the tube 84 can be made of injection molded plastic with brass compression rings added at each end and located radially between the body 26 and the tube 84 (not shown).
As best illustrated in
The opening or slit 50 is defined by two concave opposing faces 142, 144 which are elongated axially with respect to a center axis 146 of the tube 84 and meet at respective ends 148, 150 which generally form a valley sloping radially inward from the outer edge 140 and to the inner edge 138, as best shown in
When viewing a lateral cross section of the tube 84 through the center of the slit 50 which lies within a first imaginary plane disposed perpendicular to the center axis 146 (as best shown in
From about ninety degrees at the mid point 166 or first imaginary plane, the acute angle 139 generally preferably decreases with the decreasing width of the slit 50. For illustration purposes and referring to
The sharp continuous edge 138 facilitates atomizing the fuel flowing through the flow cross section generally defined by the edge 138 from the tube portion 120 and through the opening or slit 50. The opposing faces 142, 144 diverge away from one-another in a radial outward direction (i.e. the flow cross section at the outer edge 140 is larger than the flow cross section at the sharp inner edge 138) to prevent excessive fuel wetting of the faces 142, 144. The diverging faces 142, 144 combined with the fuel atomizing characteristic of the sharp inner edge 138 reduce or prevent fuel from collecting or gathering at the nozzle thus it enhances the desired mixing of fuel and air in the mixing region 122.
The length of the opening or slit 50 is preferably slightly less than an opening size or diameter 154 of the fuel-and-air mixing region 122 of the air passage 46 carried by the carburetor body 26, as best shown in
During manufacturing, preferably the opening or slit 50 of the tube 84 is cut into the tube 84 by a plunging, rotating circular cutting tool 156, which is preferably a dado blade, grinder or router bit, having a rotational axis 158 which is substantially perpendicular to the center axis 146 of the tube 84 (as best shown in
As previously described, the cross section profile of the faces 142, 144 taken at the mid point 166 of the slit 50 preferably lie along respective imaginary cutting lines 143, 145 that intersect one-another at about the center axis 146. Hence, when the blade 156 plunges into the tube 84, the cutting point 164 preferably does not plunge further than about the center axis 146 at the slit mid-point 166. The length of the slit 50 is generally dictated by the diameter of the rotating cutting tool 156. That is, the more gradual the peripheral curvature of the tool, the longer will be the slit 50 when achieving a consistent cutting depth. The circumferential angle 168 between the two imaginary cutting lines 143, 145 of the faces 142, 144 at the mid-point 166 and as designated by arrow 168 preferably lies within a range of thirty-five to sixty-five degrees and is preferably about fifty-five degrees. A desired angle 168 for a given application can be empirically determined and depends upon many parameters including fuel and air flow characteristics, fuel pressure, and the thickness of wall 134. In one presently preferred embodiment, the lower limit of the angle 168 is chosen to limit or prevent fuel wetting on the faces 142, 144 which might in some applications degrade the desired fuel mixing with air, and the upper limit of the angle 168 is chosen to prevent weakening the structural integrity of the tube 84 and needlessly complicating machining of the opening or slit 50.
A carburetor 200 according to a second embodiment of the present invention is shown in
As shown in
Therefore, fuel from a fuel supply (such as a fuel metering chamber) flows through the first portion 202 of the fuel passage 30, the bore 203, into the opening 50 of the fuel nozzle, out of the second opening 118 of the fuel nozzle 32 and through the second portion 208 of the fuel passage 30 that opens into the air intake passage 24. Fuel flow is regulated or controlled by at least the needle 86 of the second valve 34 that is slidably received in the tube 84 to vary the effective open area of the opening 50 in the tube 84 of the fuel nozzle 32. The fuel nozzle 32 and second valve 43 may be constructed as set forth in the previous embodiment carburetor 20. The second valve 34 may have the needle 86, follower 88 with fingers 92, spring 90, and stem 96 (not shown in
Persons of ordinary skill in the art will recognize that the preceding description of the preferred embodiments of the present invention is illustrative of the present invention and not limiting. Alterations and modifications may be made to the various elements of the carburetor without departing from the spirit and scope of the present invention. For example, and without limitation, while it has been disclosed in the embodiment shown that the second valve is responsive to movement of the first valve, the first valve could be responsive to movement of the second valve. Also, the first and second valves could be constructed differently and may be oriented and arranged in a manner different from that shown in the representative embodiments disclosed. The wall 134 or a portion thereof can be planar 95 instead of tubular and still carry the flared opening 50. Still other modifications are possible within the spirit and scope of the present invention.
This is a continuation-in-part of U.S. patent application Ser. No. 10/406,420, filed Apr. 3, 2003, and now abandoned in favor of this patent application.
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Number | Date | Country | |
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20050146061 A1 | Jul 2005 | US |
Number | Date | Country | |
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Parent | 10406420 | Apr 2003 | US |
Child | 11027816 | US |